Signal generator system



G. BRUCK SIGNAL GENERATOR SYSTEM Oct. 24, 1961 Filed Aug. 25,` 1959 ATTORNEYS Patented Qct. 2 4, 196.1

United l States Patent 3,005,959 SIGNAL G ENERATGR SYSTEM George BruclnWyoming, Ohio, assignor to Aveo CorpOratmm'CmCinnati, Ohio, a corporation of Delaware Filed Aug. 25, 1959, Ser. No. 835,911 6 Claims. (Cl. 331-11) The present invention relates generally to signal generators, and more particularly to'signal `generator systems arranged to provide signals at a large number ofaccurately .controlled and Widely distributed frequencies, at will, or in accordance with a predetermined` time schedule.

Briefly describing a-preferred embodiment of the present invention, a master oscillator supplies a highly stable frequency F. The frequency F is mixed in a-'rs't mixer with the outputfof a primary signal generator, V.thefrequency f of which itvis'desired to control by plural 4small increments inAf, over a range` of values of n, Where n is -an integer. There maybe'thus generated by the first mixer difference frequencies F-f r f-F, according to whether f is greater than or smaller than F. A'plurality of further fixed frequency oscillators is provided, which preferably provide exemplary fixed reference frequencies F1, 3F1, 5Fl, 7F1 respectively, i.e., frequencies mF1, Where m are odd integers having a difference of two. In the general case m may have a minimum value of either 0 or 1, so that `an alternative set of exemplary fixed frequencies may be 2F1, 4F1, 6Fl, These frequencies may be selected one at a time by an automatic programmer, or at will, and supplied to a further mixer, to which is also supplied the frequencies f*F or F-f, and selected values of output frequency derivable from the second mixer are equal to the diiference between mFl and f-F or F 1. A series of frequency discriminators is provided in cascade with the further mixer, having exemplary center frequencies yof Af, 3Af, SAf, 7Af, Whichare subject to selection one at a time by an automatic programmer, or at will, yand the selected one of which supplies A.F.C. voltage to control the frequency of the primary oscillator to have any one of a set of values of frequency equal to F inAf. Additional values of output frequency may be introduced, separated from those above Vspecified A-by adding or subtracting increments of frequency yAa to the frequency F, where y assumes integral values and Aa is a frequency increment much smaller than Af. Y

The frequency discriminators, or the selected one of these, provides automatic frequency control (A.F.C.) signal to the primary oscillator, to maintain -the frequency of the latter accurately at each value pre-selected by the programmer. The A.F.C. signal is applied to the primary oscillator via a gated polarity reversing amplifier, which may be controlledby the programmer to provide A.F.C. voltage of selectively opposite polarities in response to signal output from any frequency discriminator,

Thereby, each frequency discriminato'r establishes two:

number of xed reference frequency oscillators at frequencies MF1, to increase the upper and lower frequency limits of the system, and additional'frequency increments may be established byvproviding control of the frequency of the master oscillator, at nominal frequency F, to have further calues of F iAa, F'iZAa control frequencies for each polarity of A.F.C. voltage.

The values of fixed reference frequencies selected, i.e., mFl, are not inherently limited tofour, and that number may be increased by obvious extension of the principles of the invention. Additionally, another set of Y values than that above suggested as exemplary may beemployed for the fixed frequencies, i.e., instead of F1,

3F1, SP1, .it is possible to employ 0, 2F1,`4F1,

The total number of frequencies available to the system within any specified frequency limits maybe vexvtended by utilizing additional discriminators, o r discriminators with closer separations betweenthe center frequencies than those specied herein. The frequency range of the -system may be increased by'increasing the.,

" .It is .another object of the invention to for controlling ythe frequency v of an oscillator over a large. number of increments, where the frequencies arevin 'the' microwave region, and wherein control of frequency -Amultiple frequency generator according to the invention provides, thus, a large number of discrete frequencies, adjacent pairsof which have equal vseparations through.- out, and any one of Vthe entire gamut of available frequencies being selectable at will inresponse to a limited number'of control signals. For example, by provision for gating at will of four discriminators, four xed frequency oscillators "and two A.F.C. polarities, thirty-two frequencies become available above a reference value provided by a master oscillator. and the same.thirty-two frequencies below that reference value. Moreover, by including a master oscillator which is stepwise tunable, say in .y steps, the number yof frequencies available be- .comes 32y; More generally,.if D is-the number of frequency discriminators available, O the numberv Oflixed frequency oscillators, and iy the number of increment'sof frequency available to the master oscillator, the total number offrequencies available'to the system, above and below a.referencevalue,'is DOy.

It is essential to maximum utilization of thesystem that the frequency discriminators all have center frevquencies' lessthan the largest common facto of thefixed oscillator frequencies, F1, that they be equally spaced both from 'zero-frequency and from F1, by a frequency factor Af, and that they. be separated from eachother by 2Af. So for F1=30 mc.,.a basic frequency increment Af of 2.5 mc. Ycould be employed-.provided the set of frequency discriminators have center frequencies of 2.5 mc., 7.5. mc., 12.5 mc., 17.5 mc., 22.5 mc., 27.5 mc., a1-

-though in the preferred embodiment described herein values of 3.75 mc., 11.25 mc., 18.75 mc., and 26.75 mc.,

.are in fact employed, Af being equal to 3.75 Vmc. Y. The fixed reference frequencies such astFl and 31:1

are spaced by 60 megacycles, and inthe illustrative ernbodiment shown they are therefore spaced byy a quantity equal to ZzAf. z; in the particular case shown is equal to'tl.y g

It is, accordingly, a broad object of the present inven- 'tion to provide anovel generator of 'multiple' precisely spaced frequencies.

It is another object of the invention to provide a system for generating a large number of equally spaced frequencies, which employs a limited number of fixed fre- Vfrequencygof an oscillator over a pair of values, in response'to an automatic volume control voltage developed by: a single frequency discriminator, by selective reversal of the polarity of that voltage. L

provide a system is' accomplishedl by reference to a small number of relatively Alow frequency oscillators and frequency discriminators.I

"A furtherpbject of the present invention resides in band oscillator, wherein the oscillator is programmed to values adjacent,desiredfrequency-values by one mechathe provisionof a frequencyV control system for a wide nism, and wherein the programmed values are locked on the true values by a further mechanism.

The above and still further objects, features and advantages of the present invention will become apparent upon consideration of the following detailed description of one specific embodiment thereof, especially when taken in conjunction with the accompanying drawings, wherein:

The single figure of the drawings is a functional block diagram of a system according to the invention.

Referring now more particularly to the accompanying drawings, the reference numerals denotes a crystal controlled oscillator, generating a frequency F1, an exemplary value of which may be 30 mc. The output of oscillator 10 is applied to the input of a gated buffer amplifier 11, normally gated off and having an output channel 12, The output of oscillator 10 is also subjected to cascaded frequency multiplication in frequency tripler 13 and frequency doubler 14 and to mixing of the output of the doubler 14 with the output of oscillator 10 in a mixer 15, to provide frequencies of 90 mc., 150 mc., and 2l() mc., i.e. mF1, where F1=30 mc. The output of tripler 13 is applied to a gated 90 mc. buffer amplifier 16, i.e., one of frequency BFI, the output channel of which is 12. The output of the doubler 14, at 180 mc., i.e., 6Fl, is mixed with the output of oscillator 10 in mixer 15, to produce upper and lower side-bands at 150 mc. and 2l() mc., i.e., 5Fl and 7F1, which are separately selected by gated buffer amplifiers 17 and 18', respectively. The latter are connected to the output channel 12.

The gated buffers 11, 16, 17, 18 may be gated on at will, selectively, or in accordance with a predetermined program, by applying gating signals thereto from a programmer 20 via leads 21, 22, 23, 24, respectively. The programmer 20 may be a mechanical commutator or an equivalent electronic commutator, operative according to a sequence previously inserted, and is conventional per se and for that reason is not described in detail.

By virtue of the operation of elements 10-24 hereinabove described, a predetermined sequence. of frequencies selected from the values 30 mc., 9() mc., 150 mc., and 210 mc., i.e. F1, 3F1, 5Fl, 7F1, are applied to the channel 12. These frequencies are all locked to the output of oscillator 10. However, within the scope of the invention other multiple frequency generators can be employed, and more or fewer than four frequencies may be utilized.

The wide band voltage tunable microwave generator 30 represents the primary output generator of the system, i.e., the objective of the system is to tune the microwave generator 30 at will and rapidly to any one of a relatively large number of discrete, accurately controlled frequencies f, separated by nominal values nAf. The output of generator 30` is applied via a directional coupler 31 to a crystal mixer 32. To the latter is also supplied the output of al tunable master oscillator 33, the output frequency F of which may be fixed and remain fixed during operation of the present system, but which may 'be optionally accurately controlled over a relatively small f range of Values. 'master oscillator 33 is 5000 mc., but it may be frequency A suitable nominal frequency F for the controlled at will to have adjacent values, i.e., FiyAa, where Aa is of the order of 0.1 mc. Vand y represents a series of integers.

The output of mixer 32, equal to the difference of the output frequencies of oscillators 30 and 33, i.e., f-F or F-f depending on whether f or F is larger, is ampli- 'fied in a wide band amplifier 34 having a pass-band of output of the latter amplifier is supplied to an assembly 37 of gated amplifiers, limiters and discriminators, ar-

ranged in parallel channels 38, 39, 40, 41. Exemplary center frequencies of the discriminators of these channels are, respectively, 3.75 mc., 11.25 mc., 18.75 mc., and 26.25 mc., i.e. Af, 3Af, 5Af and 7Af. That is to say, the center frequencies of these pass bands are arranged in al series up to (z-l)Af. It has been shown that z is equal to 8 in the particular embodiment, so that this equation is satisfied. Except in respect to center frequencies the channels may be identical and accordingly only one typical channel is described in detail.

Considering the channel 38 as typical, it includes a gated amplifier and amplitude limiter 42, in cascade with a dual slope crystal controlled frequency discriminator 43. The latter may include in cascade a broad band discriminator having a frequency response characteristic as illustrated at 44, followed by a narrow band discriminator having a characteristic as illustrated at 45. The composite frequency response characteristic is shown at 46, and includes a broad band portion 47 of smallnegative slope, with a central portion 48 of sharp negative slope. Thereby, the discriminator is broad band overall, and in this respect imprecise, but provides a very accurate ultimate response, by virtue of the sharp slope of the central portion 48. The gated amplifiers and lirniters associated with channels 39, 40, 41, respectively, may be identified by reference numerals 50, 51, 52 and the discriminators by the reference numerals 53, 54, 55.

The outputs of discriminators 43, 53 and 55 and 54 are connected in parallel to a channel 56, which proceeds to an A.F.C. amplifier 527, and therefrom, via a gated polarity reversing amplifier 58, an A.F.C. voltage is applied to control the frequency of tunable microwave generatort). A positive A.F.C. voltage serves to increase that frequency and a negative A.F.C. voltage to effect a decrease therein. The gated amplifiers 42, 50', 51, 52 are selected at will by programmed control signals supplied by programmer 20 over leads 60, `61, 62, 63, respectively. The polarity of polarity reversing amplifier 58 is selected at will by a programmed signal supplied by programmer 20 via lead 64.

The programmer 20 further supplies, Via a staircase programmer voltage supply 70, :a series of discrete values of frequency control voltage to the voltage tunable generator 30. The programmer thereby commands the generator 3@ to assume, at least approximately, any one of a series of closely spaced frequencies separated by Af. It is the function of the remainder of the system to assure that the frequencies so selected and approximately assumed by the generator 30 `in response to programmed control voltage are precise and accurate, and are so maintained.

The master oscillator 33 has been described as a reference source for controlling the frequency f, which varies by frequency increments Af. it is essential that this oscillator be accurately frequency controlled, and such control is effected in the present system by means of an A.F.C. loop. The oscillator 33, which may be a reflux klystron, which is voltage sensitive, supplies its output to a pair of chambers 74, 75, each containing a semi-conductor diode, as 76, 77, coupled to the master oscillator 33. Associated with and coupled to the chambers 74, 75 is a high Q resonant cavity '7 8. The semi-conductor diode 77 is connected to the input circuit of an LF. amplifier y79, and the semiconductor diode 7'6 is connected to its output circuit. The resonant cavity 78 is tuned to one of the sum and difference of the desired frequency of master oscillator 33 and the frequency of LF. amplifier 79, which is relatively narrow band, or high Q. 'For the sake of example, we may assume the desired frequency of the master oscillator 33 to be 5000 me., and the frequency of the LF. amplier 79 to be 30 mc. The resonant cavity 78 may then be tuned to 5030 nic.

If now we assume some output from LF. amplifier 79 at 30 mc., mixing of this output in diode 76 with the output of the master oscillator 33 at 5000 mc. will provide a sum frequency at 5030 mc. to which the resonant cavity 78 is resonant. The resonant cavity 7=8 in turn is' coupled with the semi-conductor diode V77, which produces a difference frequency of 30 mc. in response to the signal in the resonant cavity, i.e., 5030 mc. and the signal provided by the master oscillator 36, i.e., 5000 mc. The LF. ampliier may be provided with sufficient gain at its resonant frequency to maintain oscillations, by virtue of the above described process, around the loop consisting of diodes 75, 77, resonant cavity 7S, and LF. amplifier 79, provided the total phase shift around the loop is Zirnf c.p.s., where n is any. integer.

If now the frequency of the master oscillator 33 varies, the total phase shift around the loop is caused to vary because the Q factors of the cavity 78 and the LF. ampliier 79 are-radically different, and it is Q factor which establishes phase shift per cycle per second of frequency change in a resonant circuit. Variation of the total phase shift about the loop causes a compensating change in the frequency'of oscillations in the loop, normally at 30 mc. The frequency of oscillations in the loop is thus a function of the'frequency of the master oscillator 33, and the relation isl such that a very small percentage change in the frequency of master Ioscillator 33 isvreflected as a very large percentage change in loop frequency.

Control voltages supplied to the lead 71 by programmer 20 serve', as described below, to adjust the frequency of reference generator 72 by small increments, intermediate the 3.75 mc. increments otherwise available. For example, five increments of 0.1 mc. each may be provided. These increments are sufiiciently small' that the available set of discriminator channels 37 is adequate to capture and hold the frequency of generator 30, i.e., the width ofthe response characteristic 46 of each discriminator is greater than 3.75 mc., which is adequate for the suggested increments.

The tunable reference oscillator ,'12 includes a crystal controlled oscillator 80, providing 29 mc., connected in cascade with a positively counting counter type frequency discriminator 81. A variable oscillator 82 is provided, which is connected in cascade with a negatively counting counter type frequencygdiscriminator 83. 'I'he counter type discriminatori-s `81'1and `83 supply voltages correspond- .ing with their counts to the comparator 84, which supplies vitsfdifference or error output-voltages as an A.F.C. voltage to a reactance tube frequency control circuit 85 associated with oscillator 82. Since the counts of discriminators 811 and 83 are equal while the frequencies of oscillators 80 and S2 aire equal, and become relatively greater and smaller according as the frequency of oscillator 80 is below. or above the frequency of oscillator 82, the system continuously maintains the frequency of oscillator 82 equal to the frequency of oscillator 80. However, a control yvoltage can be inserted into either counter, additive of the normal output voltage to the counter, and in such case a fixed frequency difference may be maintained between the outputs of oscillators 80 and 82, which is a function of the control voltage. v

The'foutput frequency present on lead 73, .equal to the frequency of crystal controlled oscillator 80 plus or minus an increment of frequency affected by control voltage .applied to counter 83 over lead 71 from programmer 20, lis supplied to a frequency control circuit associated with master oscillator 33.

yOutput signal provided by LF.` amplifier 79, which is a function of the frequency of master oscillator 3,3, is sup- `plied tov an amplifier 86, which in turnrtransfers this frequency, nominally 30 mc., to a mixer 87. To the latter is also supplied-the output of tunable reference frequency 72, nominally at 29 me., Via a lead 73. The mixer prod- -uct is suppliedto a 1.0 me. frequency discriminator 83,

which supplies A.F.C. voltage to master oscillator 33, in such polarity that constancy of output frequencies of oscillator 33 is maintained.

tion in output frequency of master oscillator 33. If, for example, the nominal frequency provided by, oscillator 72, i.e., 29 mc., be increased by a frequency'increment Aa, the difference frequency applied Vto discriminator 88 is reduced, and the latter developes a positive A.F.C. voltage for application to master oscillator 33, tending to increase the frequency of the latter. Increase of output frequency of master oscillator 33 effects a corresponding increase in the output of amplifier 79, which continues until amplifier 79 has acquired a frequency increase of Aa, whereupon the A.F.C. loop comprising discrirninator 88 is satisfied. It will be obvious that, if frequency discriminator 38 is to' have a zero response point at 1.0 mc., Aa must be much smaller than,1.0 rnc. Inprinciple, however, other frequency relations than the exemplary ones specified may be employed if larger values of Aa are to be permitted.

The values lof frequencies which may be scheduled in the exemplary embodiment of the present invention herein described are, where the column headings indicate which one of gated buffers 11, 16, 17, 18 is gatedon,

The values of frequency available at the output of the rst mixer 32 are f-F or F -f, depending on whether f is greater than or smaller than F. These difference values may be denominated Inf] and |-Af|, respectively.

The vertical lines in these expressions signify the summation of Af increments which have been generated by Vthe first mixer. That is, |Af| may be Af, 3Af,5Af, or any odd multiple of Af up to 63Af. The second mixer then provides output at frequencies mFl-[Afl or depending on which frequency is greater, mF1 or lAfl. In each mixer, then, only subtractive heterodyne products are employed. f

Assuming F, in describing A.F.C. action in the present system, if [Alf is slightly larger than called for by the system mF1-|Af| will provide a positive error signal `and [Af|mF1 will provide a negative error signal tothe v A.F.C. loop, since the discriminatorshave negativerslopes with increasing frequency. Oppositely poled A.F.C. Volt ages are therefore required for these cases, since a positive A.F.C. signal increases f and hence IAfI, whereas a Vnegative VA EC.- voltage decreases f and therefore IAlf.

The outputs of frequency discriminators 43, 53, 54, 55 are required to be positive for positive error signals, and vice versa. Therefore, for the case f F, if |A|f mF1, and if Inf] ishigher than called for by thek frequency discriminators, so that the latter provide positively poled output, the latter may be applied with polarity reversal as A.F.C. voltages. On the other hand, for mF1 IAfl polarity reversal is not-required.

If F f, i.e., [Afl is negative, the second mixer again provides outputs MF1-[Afl or [AH-MF1.y In orderto decrease IAfl it is necessary to increase f, i.e., to apply a positive A.-F.C. voltage' to primary generator 30, and alternatively to increase lA'fI it is necessary to4 decrease. f, by means of a negative A.F.C. voltage.

If |Af| is too'great, and if [Af| mF1, [Afl-MF1' will be too great, a positive voltage will be provided by frequency discriminators 43, 53, 54, 55 landv polarity reversal. of this A FC. voltage is not required, since an These conditions are met by properly programming the gated polarity reversing amplier 58.

In order further to explain the operation of the system, by reference to exemplary values of frequency, as-y sume that the frequency of primary generator 30 to be slightly higher than adesired value of 5003.75 mc., say by an increment Ax. The output of mixer 32 Would then be higher than 3.75 by the same increment Ax, but the output of the mixer 35, equal to 30-(3.7 5 -l-Ax) mc., is lower than 26.25 mc. by the increment Ax. The response of the dual slope discriminator 55 is then positive in polarity. This positive polarity is reversed in gated polarity reversing amplifier 58, and applied as a negative A.F.C. voltage to primary generator 30, reducing the frequency of the latter to its true value, i.e., 5003.75 mc.

For desired values of output frequency of generator 30 equal to 5011.25 mc., the generator 30 is programmed to approximately that frequency. The mixer 32 then supplies an output frequency of 11.25 mc., and the mixer 35 a frequency of 30-l1.25 :18.75 mc. The gated arnplier and limiter 51 is programmed into the system, gated polarity reversing amplifier is programmed to polarity reversing condition, and the A.F.C. voltage provided by dual slope discriminator 54 locks the generator 30 on frequency. Analogous operation occurs for frequencies 5018.75 and 5026.25, these frequencies involving, however, dual slope discriminators 53, 43, respectively.

In order to generate a frequency 5033.75, the generator 30 is programmed approximately to that frequency. The mixer 32 now supplies a frequency of 33.75 mc. which combines in mixer 35 with 30 rnc. deriving from gated buffer 11 to provide 3.75 mc. for application to discriminator assembly 37. Assume now that the generator 30 is high in frequency by an increment Ax. The output of mixer 32 will be high by the same increment Ax, and the output frequency of mixer 35 will likewise be high by increment Ax, since the latter frequency equals 33.75-30 mc. Accordingly, the output of dual slope discriminator 43 will be negative, which is the correct polarity for reduction of the increment Ax to zero. In this set of circumstances the gated polarity reversing amplifler is programmed to pass A.F.C. voltage without polarity reversal.

By analogous reasoning it can be shown that each of frequencies 500-|-(42.25, 48.75, 56.25) may be generated without polarity reversal of A.F.C. voltage.

Should it be desired to programme a frequency of SOOO-3.75 mc. for example, the output of the mixer 35 will be 30-3.75=26.25 mc. Hence, programming for SOOO-3.75 mc. involves the same reference frequency mF1 and the same frequency discriminator 55 as for 5003.75 mc. Should the output frequency of generator 30 below, i.e., 5000-(3.75+Ax), however, where the desired frequency is 500G-3.75 rnc. the output of the mixer 32 will be (3.75-i-Ax) mc., and the output of the second mixer 26.25-Ax.

The output of the frequency discriminator 55 will then be positive in polarity, which is the polarity required to raise the frequency of generator 30 until Ax becomes zero, and polarity reversal at gated polarity reversing amplifier 58 will not be required.

In general, it may be shown by tracing through polarity requirements for each possible frequency Fi[Afl, Where IAfI is given by Table I, that AFC. polarity is correct for the first half of each column, and of reversed polarity for the last half, if f F, and that opposite conditions obtain for F f. It may also be. shown that, in proceeding down any column of Table I, the dual frequency discriminators to be programmed in circuit are in order, 55, 54, 53, 43, 43, 53, 54, 5S.

The operation of the present system remains the same for a small range of frequency variation of master oscillator 33, the programmed frequency increments listed in Table I remaining correct, but the basic frequency with which these frequency increments must be combined to arrive at the programmed frequencies is changed in consonance with the frequency of master oscillator 33. The frequency of master oscillator 33 being F, the frequency of primary generator 30 is F inAf, regardless of the value of F, where nAf are the frequency increments listed at Table I. However, considerable discretion must be exercised in selecting frequency values for master oscillator 33, in View of the band-width of frequency discriminator S0 and of the fact that primary generator l30 is programmed bly a single programmer designed primarly for only one master oscillator frequency.

Frequency programming of master oscillator 33 may be dispensed with entirely, if desired, without departing from the basic conception on which the present invention depends, and if included in a practical embodiment of the invention may be considered fto involve Va permissive irnprovernent.

It will be understood that randomor progressive output frequency selection may be made in a matter of a few microseconds from any point in the output frequency spectrum to any other point. The system herein shown can be programmed to provide an extremely rapid frequency sweep, so that it is of unique utility for driving a steerable antenna array in a track-while-scan system.

While I have described and illustrated one specific embodiment of my invention, it will be clear that variations of the details of construction which are specifically illustrated and described may be restored to without departing from the true spirit andl scope of the invention as dened in the appended claims.

What I claim is:

1. A signal `generation system, including a source of signals at frequency F, a generator having a frequency f to be controlled accurately step-wise over a wide range of frequencies by increments Af, the frequency'F approximating the center frequency of said generator, means for heterodyning the frequency F with the frequency f, toV

provide frequencies f-F or F-f, means for providing any one of a plurality of fixed frequencies mF1, where m has values differing only by increment-s of two, a heterodyne device having an input circuit and an output circuit, means for supplying the selected one of said fixed frequencies and the frequencies f-F or F-f to said input circuit of said heterodyne device for heterodyning therein to provide a frequency equal to the difference between mF1 and [(f-F) or (F -f)], a plurality of frequency discriminators connectable selectively to the output of said heterodyne device, said frequency discriminators having each output voltages of opposite polarities in response to applied frequencies of opposite senses with respect to a predetermined center frequency, the center frequencies of said frequency discriminators having values nAf, where n are integers different by a factor of two, and where said center frequencies are lower than the frequency F1 and symmetrically arranged between the frequencies zero and F1, and an automatic frequency control channel coupled from said `discriminators to said generator, Af being a common factor of the frequency mFl.

2. A controllable signal generator system including a master oscilllator of frequency F, a generator controllable in respect to frequency f over a wide band of frequencies centered at F, means for obtaining a difference frequency from said generator and master oscillator, a source of accurately controllable frequencies selective from among values mF1, where the values of m are integers differing by two, a heterodyne device having an input and an output, means for coupling said difference frequency and said source -to said input to provide further difference frequencies at said output, a plurality of frequency discriminators connectable one at a time to said output, means connected between said discriminators and said generator for supplying automatic frequency control signal to said generator, said frequency discriminators having center point frequencies at nAf, where n are odd integers, and where said center point frequencies are distributed symmetrically between zero frequency and frequency F1.

3. In a signal generation system, a master oscillator providing a signal of frequency F, a primary signal generator providing a signal of frequency f centered at F, means responsive to said master oscillator and said primary signal generator for providing signals of frequencies equal -to the difference of frequencies F and f, respectively, wherein the frequency f may have a wide range of values extending both below and above the frequency F, and wherein the frequency assumes a multiplicity of discrete valves F inAf, where n are integers adjacent ones of which are separated by a factor 2, a source of further frequencies mF1 where m are integers separated by a factor of two, mixer means for deriving heterodyne products of mF1 with said difference of frequencies F and f, respectively, and a series of automatic frequency control circuits operatively responsive to said heterodyne products and selectively coupled to said primary signal generator in frequency controlling relation thereto, said automatic frequency control circuits including frequency discriminators having inputs selectively coupled to said mixer means and tuned to a different one of frequencies between and F1 and spaced by 2Af.

4. The combination according to claim 3 wherein is included a selective polarity inverting element between the output of said frequency discriminators and said primary signal generator.

5. A signal generator comprising:

tunable means for generating signals of a frequency f, adjustable by incrementsy or decrements inAf, each equal to a fraction of a predetermined reference frequency F1,

means for generating signals of a grequency F,

a first mixer for heterodyning together the two abovementioned signals to derive first resultant signals having a frequency equ-al to F (f-nAf) or (-i-"A-F,

means for generating fixed reference frequency signals of frequencies F1, 3F1, 5F1, 7F1,

a second mixer in cascade with the first mixer for heterodyning together a selected one of the fixed reference frequency signals and the first resultant signais,

a first amplifying filter having a pass band from 0 to F1 and not wider than F1,

a plurality of second amplifying filters each adapted to be selectively coupled to said first amplifying filter and having narrow pass bands and center frequencies of Af, 3Af, SA, and 7M, respectively.

a plurality of discriminators individually coupled to said second amplifying filters and having center frequencies of Af, 3M, SAf, and 7M, respectively,

means for adjusting the tunable means to frequencies of finAf and simultaneously selectively coupling the appropriate one of said second amplifying filters to said first amplifying filter,

means for selecting and applying to the second mixer that one of the reference signals which causes the second resultant signals to be Within the pass band of the first amplifying filter,

and means for applying to the tunable means as an automatic frequency control potential the output of the selected one of said discriminators with a polarity dependent on whether or not said nAf is greater or less than the frequency of the reference signal being utilized and on whether or not nAf is positive or negative.

6. A signal generator comprising:

tunable means for generating signals at a frequency f, adjustable by increments or decrements innf, each equal to a fraction of a predetermined reference frequency F1,

means for generating signals of a frequency F,

a first mixer for heterodyning together the two abovementioned signals to derive first resultant signals having a frequency equal to F-(f-nAf) or (f-I-"A-F,

means for generating fixed reference frequency signals of frequencies F1, F14-22M, F1+4zAf, F1|6zAf, etc., where z is an even number,

a second mixer in cascade with the first mixer for heterodyning together a selected one of the fixed reference frequency signals and the first resultant signals,

a first amplifying filter having a pass band from 0 to F1 and not Wider than F1,

a plurality of second amplifying filters each adapted to be selectively coupled to said first amplifying filter and having narrow pass bands and center frequencies of Af, 3Af, in a series up to (z-UAf, respectively,

a plurality of discriminators individually coupled to said second amplifying filters and having center frequencies of Af, 3Af, in a series up to (z-l)Af, respectively,

means for adjusting the tunable means to frequencies of ftnAf and simultaneously selectively coupling the appropriate one of said second amplifying filters to said first amplifying filter,

means for selecting and applying to the second mixer that one of the reference signals which causes the second resultant signals to be within the pass band of the first amplifying filter,

and means for applying to the tunable means as an automatic frequency control potential the output of the selected one of said discriminators with a polarity dependent on whether or not said nAf is greater or less than the frequency of the reference signal being utilized and on whether or not nAf is positive or negative.

References Cited in the le of this patent UNITED STATES PATENTS UNITED STATES PATENT OFFICE CERTIFICATE OF CORRECTION Patent No. 3,005,959 October 24, 1961 George Bruck It is hereby certified that error appears in the above numbered patent requiring correction and that the said Letters Patent should read as corrected below. 1

Column 2, line 6, for "calues" readl values --g line 37, for "26,75" read 26.25 --3 column 3, line ll, for "numerals" read numeral column 6, lines. 50, 57, and 60, for IMT", each occurrence, read lf column. 8, line 40, or "restored" read resorted line 69, for ',*requem read frequencies column 9,y line 22, for "valves" read values line 37, for "output" read outputs" --5 line 44, for "grequency"` read -vfrequency ;v same column, line 60, for "respectivelyl."r read" respectively,

Signed and sealed this 8th day of May 1962,

(SEAL) Attest:

ERNEST w SwIpEE DAVID L. LADD Attestng Officer v Commissioner of Patent 

